Thiamin Stability. Effect of Amino Acids and Related Compounds and

Floyd C. McIntire, and Douglas V. Frost. J. Am. Chem. Soc. , 1944, 66 (8), pp 1317–1318. DOI: 10.1021/ja01236a033. Publication Date: August 1944...
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Aug., 1944

EFFECT OF AMINOACIDSAND RELATED COMPOUNDS ON THIAMIN STABILITY

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[CONTRIBUTION FROM THE ABBOTTLABORATORIES]

Thiamin Stability. Effect of Amino Acids and Related Compounds and of Thiamin Concentration’ BY FLOYD c. MCINTIREAND DOUGLAS v. FROST The problem of thiamin stability has received attention in this Laboratory for some time.2 That the rate of thiamin decomposition ih aqueous solutions is dependent upon acidity and increases markedly with a rise in pH above 4 is well e s t a b l i ~ h e d . ~There ~ ~ ~ ~is- good ~ ~ ~ evidence that in pure thiamin solutions the destruction by heat is primarily a hydrolytic cleavage to give 2methyl-5-hydroxymethyl-6-aminopyrimidine and Infor2-methyl-3- (,&hydroxy)-ethylthiazole. mation is accumulating to show that the presence of other compounds in solution with thiamin may increase or decrease its rate of destruction a t a given pH value Williamss pointed out that barium nitrate and sodium acetate as well as bisulfite would hasten thiamin destruction] while Beadle, et UZ.,~ and Booth4 have indicated that the rate of thiamin decomposition varies with different buffer salts as we11 as acidity. Booth4 also showed traces of copper accelerated thiamin decomposition while several other heavy stated that metals had no effect. Melnick, et UZ.,~ thiamin is more stable in a natural environment than in synthetic solutions and it has been reported that some proteins’O and starch” markedly decrease the rate of thiamin destruction under certain conditions. It has also been reported that thiamin is quite unstable in some meat products and that the addition of certain cereals has a remarkable stabilizing effect.12 The purpose of this paper is to show that a-and p-amino acids have a marked stabilizing effect upon thiamin and that in pure thiamin solutions the stability depends upon thiamin concentration. The effect of amino acids is most pronounced in the presence of some salts which hasten the destruction of thiamin. The a- and @-amino acids nullify the destructive effects of Such salts. Studies on the relationship of chemical structure to this stabilizing effect will, be,presented. Experimental



Crystalline thiamin chloride hydrochloride and tripledistilled water were used throughout. Solutions were ad(1) Presented in part before the American Chemical Society a t Pittsburgh, Pennsylvania, September 9, 1943. (2) Frost s a d McIntire, THISJ O U R N A L , 66, 425 (1944). (3) Farrer, Australian Chem Znsl. J . & Proc., 8 , 113 (1941). (4) Booth, Biochem. J . , 37, 518 (1943). ( 5 ) Beadle, Greenwood and Kraybill, J . Biol. Chcm., 149, 338 (1943). (6) Williams, J . A m . M e d . Assoc., 110, 727 (1938). (7) ( a ) Watanabe. J . Pharm. SOC.j a p a n , 69, 218 (1939); (b) 500 (1939). (8) Schepfer and Muller, C o n t p f . rend. SOL. biol., 128, 372 (1938). (9) Melnick, Robinson and Field, J . Biol. Chcln.. lS6, 49 (1041). (10) Greenwood, Beadle and Kraybill, i b i d . , 149, 349 (1943). (11) Atkin, et ai., U . S. Patent 2,322,270 (1943). (12) Rice. Beuk and Robin8on, Scirnce. 98, 449 (1943).

justed with dilute sodium hydroxide and hydrochloric acid to PH 6 * 0.05. Solutions t o be heated were sealed in 20mi. flint glass ampules, placed in boiling water for about ten minutes, and then transferred to an oil-bath and maintained at 100 * 1O for four hours. After heating, the ampules were cooled in ice water and kept cool until analyzed. Thiamin was determined by the thiochrome method. All figures are representative of two or more concordant experiments. I n samples containing amino acids very little PH change occurred during the heating period. In pure thiamin and thiamin plus sodium chloride solutions the PH always dropped to about 5.2 and 4.3, respectively, during the heating period. Stabilizing Effect of a- and 8-Amii0 Acids.-The data in Table I show that a- and &amino acids and some of their derivatives have a marked Stabilizing effect upon thiamin a t PH 6. This effect becomes noticeable above pH 4.5 to 5, depending upon the concentration of thiamin and other factors, and its magnitude increases with a decrease of acidity within the range studied, namely, pH 4.5 to 7. As will be shown later in Table 11, the stability of thiamin varies with thiamin concentration. A t the concentration chosen for the data of Table I, i. e., 0.1 mg. per nil., thiamin alone is much more stable than it is in the presence of sodium chloride and other salts. Consequently, a t this concentration of thiamin the stabilizing effect of the amino acids is demonstrated better with thiamin plus sodium chloride than with thiamin alone.

TABLE I RELATIONSHIP OF CHEMICAL STRUCTURE TO EFFECTON THIAMIN STABILITY Compound added,

M/20

None (control) Glycine Glycine amide Glycylglycine Acetylglycine Sarcosine N- Dimethylglycine Betaine Taurine &Alanine y-Aminobutyric acid I-Aminovaleric acid e-Aminocaproic acid Anthranilic acid m-Aminobenzoic acid p-Aminobenzoic acid Choline chloride Creatine Acetamide Nicotinic acid Nicotinamide Benzylamine Allylamine Diallylamine Tributylamine n-Bu tylamine Di-n-butylamine

Per cent. thiamin remaining after four hours a t l o O D , pH 6 Thiamin alone, Thiamin 0.1 mg./cc. 0.1 my./cc. in M/20 NaCl

73 79 8-1

82 78 78

.. ..

57 84 84 85 34 75 80

72

58 78

..

382

27

22 14

.. ..

19

73 58 23 63

70 59 21 57 48 14 23 13

22

.. 35 17 80 73 80 78 47 46

74

61 77 76 48 44

11 THIAMIN STABILITY AT DIFFERENT CONCENTRATIONS, MINIMUM EFFECTIVE CONCENTRATION OF GLYCINE TABLE

Per cent. thiamin remaining after four hoiirs at looo,p H G M/20 glycine 41,'lOOO xlycine

Original thiamin concentration, mg. per CC.

N o glycine

0.001 .01 1 1 in 61/20 NaCl

35 73 57

8

70 79 79 84

iti ifi

79

-I2

may be replaced by the sulfonic acid group without appreciable loss of the thiamin stabilizing property. Benzylamine and diallylamine had a definite stabilizing effect. Several saturated primary, secondar.y, and tertiary aliphatic amines were tested but only tri-n-butylamine had any stabilizing effect. All others, including n-butyland di-n-butylamines had a destructive effect approximately equal to t h a t of sodium chloride. Of practical pharmaceutical significance is the marked destructive effect of nicotinamide and nicotinic acid. The above findings may be related to the destructive and protective effects upon thiamin in different biological material^.^,^^,'^ They have no apparent relation to the enzymatic inactivation of thiamin.13si4 Effect of Thiamin Cwcentration. Minimum Effective Concentration of Glycine. -The data of Table I1 illustrak th-t in pure thipmin solutions the rate of drc:ompositioii varies with the cgncentration of thiamin. I n the niorc' concentrated solutions examined, thiamin was much mort. stable than in the very dilute solutions. The stabilizing effect of amino acids is best demonstrated at low concentrations of thiamin. The data of Table I1 also show that a nearly maximum thiamin-stabilizing effect is produced by as little as M/1000 glycine, even at very low concentrations of thiamin or in the presence of M/20 sodium chloride. Concentrations of glycine lower than M/l000 gave irregular results regardless of thiamin concentration. No clear-cut stoichiometric relationship between thiamin concentration and minimuni effective glycine concentration was found. With 0.1 mg. of thiamin per ml., an equal molar concentration of glycine, i . F., :ll/8:370, was effective in some experiments.

Several other salts includitig chlorides, bromides and acetates were tested arid were found t o increase the rate of thiamin decompositioii. In general, the acetates had the greatest effect. In all cases the destructive effects of salts were nullified by glycine. Most of the a-amino acids, including the inonoaminodicarboxy and diaminomonocarboxy acids, have been tested. All except cysteine are approximately equally effective in stabilizing thiamin. The data for glycine are shown as representative. The fact t h a t cysteine has little or no stabilizing effect upon thiamin might he owing to its sulfhydryl group since cystine is very effective even at its low level of solubility. @-Alaninewas fully as effective as the a-amino acids. Relation of Structure to Thiamin-Stabilizing Property. .-'I'he relationship of chemical structure to the thiaminbtabilizing property of amino acids was investigated with respect t o (1) substitutions in the amino and carboxyl groups, (2) the relative positions of the amino and carboxyl groups, and (3) replacement of the carboxyl by other strongly negative groups. In addition, the effect of various Acknowledgment.--The authors are grateful amines and a few miscellaneous dipolar compounds was to Jean Heinsen for technical assistance, and to examined. The data are summarized in Table I. The carboxyl group may be substituted to form the E. 0. Krueger, Dorothy Washburri and Jean amide without loss of activity, e . g., glycine amide. In this Klumb for thiamin determinations. respect glycylglycine may be considered a substituted glycine amide. Acetylation of the amino group destroyed Summary the thiamin-stabilizing property, but substitution of 1 or 2 The cy- and p-amino acids decrease the rate of methyl groups in the amino group did not. However, conversion t o the quaternary ammonium base, betaine, thiamin decomposition. This effect of amino did destroy the stabilizing quality. acids is strong enough to nullify #e destructive The relation of effect upon thiamin stability to the relative positions of the amino and carboxyl groups is quite effect of certain salts upon thiamin. Investigation of the relationship of chemical striking. Compounds with the amino groups on the aor P-carbon atom had approximately the same stabilizing structure to the thiamin-stabilizing property reeffect, b u t when the amino group was removed farther vealed that y-, 6- and €-aliphatic amino acids and from the carboxyl, a marked destructive effect was obp-aminobenzoic have a marked destructive effect tained. In a n amino acid having both a n a- and an Camino group, e. g., lysine, the effect of the a-amino group upon thiamin. predominates since lysine. had approximately the same The stability of thiamin varies with the coneffect as glycine. centration. At 0.1 mg. per ml. thiamin is much The position of the amino group relative t o the carboxyl is important also in the aminobenzoic acid series. Thus more stable than a t 0.001 mg. per ml. anthranilit acid was protective, m-aminobenzoic had no NORTH CHICAGO, ILL. RECEIVED MAY23, 1944 noticeable effect, and p-aminobenzoic was destructive toward thiamin. I n some compounds, ('. g., taurine., the carboxyl group